高浓度有机络合镀镍废液及清洗废水处理工艺实验研究
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摘要
本课题以咸阳彩虹集团电镀镍钨生产线所产生的高浓度有机络合剂镀镍废液及清洗废水为研究对象,对废水的处理及回用进行实验研究。针对高浓度有机络合镀镍废液提出了减压蒸发浓缩—结晶处理工艺流程。实验数据表明:负压下废液的沸腾温度降低,压力为0.035MPa(绝对压力)时,沸腾温度为73℃,使加热蒸汽与沸腾液体间的温度差增大,可减小蒸发器的面积,同时减少对外界的热损失。减压蒸发浓缩3倍时,二次蒸汽吸收液中镍含量最高为0.15mg/L,COD为9.4mg/L,既可作为清洗水回用又可达标排放。浓缩后的废镀液再进行蒸发结晶处理,蒸发结晶产生的干渣量少(254.3kg/m~3),干渣中镍的含量高达5.3%,可送冶炼厂回收金属镍。电镀清洗废水采用超滤—反渗透膜分离工艺进行浓缩处理,透过液作为清洗水回用,浓缩液与废镀液一起进入减压蒸发浓缩—结晶工艺过程进行处理。实验表明,超滤作为反渗透的预处理工艺,超滤膜选用截留分子量为10000的聚醚砜膜(PES)比较合适;反渗透膜分离工艺(RO)对镍及COD具有很高的去除率,运行初期分别为99.4%和99.4%,在运行结束,透过液回收率为50.75%时,RO工艺对镍及COD的去除率分别为93.49%和93.4%。若透过液作为清洗水(镍浓度应小于20mg/L)回用,则浓缩倍数不应超过1.8倍。本论文所提出的减压蒸发浓缩—结晶处理高浓度络合镍废水及超滤—反渗透膜分离工艺对清洗水进行浓缩处理的工艺流程,实现了对废水的综合治理,即:重金属回收、清洗水回用。该工艺运行操作简单,不需要外加化学药剂,仅需耗用蒸汽,不会对环境造成二次污染,具有广泛的实用价值。
The research is about the treatment of high concentrated organic chelate nickel plating liquid and the rinse water generated in the manufacturing line of XiariYang Rainbow Grop. We concertrated the experiment on the disposed and recircling of the waste water. The waste liquid is processed by decompression-evaporation and concentration crystallizing. Experimental data illustrate that boiling temperature lowed by decompressing the pressure of the waste liquid to negative pressure, for example, when the absolute pressure is 0.035Mpa, the boiling temperature is 73℃.This process increases the temperature head between heating water and boiling waste liquid, meanwhile decreases the surface of evaporator and heat loss. When the waste liquid is concentrated to a concentration that three times higher than the original liquid by the process of decompressing-evaporation, nickel content in the secondary vapor absorbent is 0.15mg/L at most; COD is 9.4 mg/L, which reach the recycling and discharging standard. The condensed
waste liquid is disposed by evaporation-crystallizing process, which generates remains contained 5.3% nickel that can be recycled by the smeltery. Nickel plating rinse water is disposed by the process of ultrafiltation-reverse osmosis membrane separation technique. Filtered water is recycled. Concentrated rinse water disposed by decompression-evaporation and concentrating-crystallizing process together with the waste water. Experiment illustrates that used as pre-disposal technique in the process of RO, selecting membrane PES-10000 as ultrafiltation membrane is suitable; RO technique is efficient in nickel and COD removal The removal ration is 99.4% separately, in the incipient operation and 93.45%, 93.4% separately, when recovery coefficience of ultrafiltration is 55.75%.The coneertration of rinse water is below 1.8 times than the original rinse water when the filtered water is used as cleaning water(nickel coneertration is lower than 20 mg/L). The
technique of decompression-evaporation and concertration-crystallization in disposing high concentrated organic chelate nickel plating waste liquid and ultrafiltration- RO membrane separation in disposing rinse water which are put forward in this paper make it possible for comprehensive ultilization of waste water, i.e. recycling of heavy metal and rinse water. The technique is of great applied value. It is easy for operation. Except for vaper heat source, no additional chemical agent is needed, which will keep away from the secondary pollution.
The research is about the treatment of high concentrated organic chelate nickel plating liquid and the rinse water generated in the manufacturing line of XiariYang Rainbow Grop. We concertrated the experiment on the disposed and recircling of the waste water. The waste liquid is processed by decompression-evaporation and concentration crystallizing. Experimental data illustrate that boiling temperature lowed by decompressing the pressure of the waste liquid to negative pressure, for example, when the absolute pressure is 0.035Mpa, the boiling temperature is 73℃.This process increases the temperature head between heating water and boiling waste liquid, meanwhile decreases the surface of evaporator and heat loss. When the waste liquid is concentrated to a concentration that three times higher than the original liquid by the process of decompressing-evaporation, nickel content in the secondary vapor absorbent is 0.15mg/L at most; COD is 9.4 mg/L, which reach the recycling and discharging standard. The condensed
waste liquid is disposed by evaporation-crystallizing process, which generates remains contained 5.3% nickel that can be recycled by the smeltery. Nickel plating rinse water is disposed by the process of ultrafiltation-reverse osmosis membrane separation technique. Filtered water is recycled. Concentrated rinse water disposed by decompression-evaporation and concentrating-crystallizing process together with the waste water. Experiment illustrates that used as pre-disposal technique in the process of RO, selecting membrane PES-10000 as ultrafiltation membrane is suitable; RO technique is efficient in nickel and COD removal The removal ration is 99.4% separately, in the incipient operation and 93.45%, 93.4% separately, when recovery coefficience of ultrafiltration is 55.75%.The coneertration of rinse water is below 1.8 times than the original rinse water when the filtered water is used as cleaning water(nickel coneertration is lower than 20 mg/L). The
technique of decompression-evaporation and concertration-crystallization in disposing high concentrated organic chelate nickel plating waste liquid and ultrafiltration- RO membrane separation in disposing rinse water which are put forward in this paper make it possible for comprehensive ultilization of waste water, i.e. recycling of heavy metal and rinse water. The technique is of great applied value. It is easy for operation. Except for vaper heat source, no additional chemical agent is needed, which will keep away from the secondary pollution.
引文
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2.吴仲达等.电镀基本原理与实践.北京.机械工业出版社,1986
3.涂锦葆.电镀废水治理手册.北京.机械工业出版社,1989.
4.黄渭澄等.电度三废处理.成都.四川科学技术出版社,1983
5.张镜清.镍的毒性和含镍废水的治理.电镀与环保,1987,7(4):33~34
6.杜仰民.利用腐殖酸树脂处理镀镍废水.环境工程,1995,11(3):21~25
7.郑领英等.膜技术.北京.化学工业出版社,2000
8.王学松.反渗透技术及其在化工环保中的应用.北京.化学工业出版社,1988
9.王小文.超滤法处理碱法草浆黑液的试验研究.西安建筑科技大学硕士学位论文,导师:金奇庭,1998
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11.唐受印等.水处理工程师手册.北京.化学工业出版社,2001
12.[英]J.K.丹尼斯等著.镀镍和镀铬新技术.北京.科学技术文献出版社,1990
13.时钧等.膜技术手册.北京.化学工业出版社,2001
14.[日]中村实等著.电镀废水闭路循环的理论与应用.北京.机械工业出版社,1986
15.罗耀宗等.废槽边镀镍化学法处理含镍废水.1992,8(4):17
16.化学工业物性数据手册.有机卷.北京.化学工业出版社,1995
17.[美]Zahid.Amjad主编.反渗透—膜技术.水化学和工业应用.北京.化学工业出版社,1999
18.张自杰.排水工程(下)(第四版).北京.中国建筑工业出版社,1995
19. George C. Cushnie, Jr. ELECTROPLATING WASTERWATER POLLUTION CONTROL TECHNOLOGY. 1985
20.沈品华。电镀废水治理方法探讨.电镀与环保,1998,18(3):28~31
21.孟祥和等.重金属废水处理.北京.化学工业出版社,1999
22.崔志律,何为庆.工业废水处理.第二版.北京.冶金工业出版社,1999
23.电镀废水治理技术综述.北京.中国环境科学出版社,1992
24.王九思等.水处理化学.北京.化学工业出版社,2002
25.巩志坚,靳瑛.利用芬顿试剂处理焦化废水,工业水处理,1997,17(6):4~6,
26.云桂春,E·吉尔伯特,S·H·艾伯勒.用H_2O_2/Fe~(2+)处理含蒽醌—2—磺酸(ASA)染料
废水的实验研究,水处理技术,1987,13(4)
27.徐向荣,王文华,李华斌.Fenton 试剂处理酸性染料废水的研究,环境导报,1997,6:23~24
28.肖羽堂,许建华.利用芬顿试剂预处理难降解的二硝基氯化苯废水,重庆环境科学,1997,19(6):33~36
29.朱慎林等.环境化工技术及应用.北京.化学工业出版社,2003
30.刘旗龙.超滤在草浆黑液处理中的应用研究.西安建筑科技大学硕士学位论文,导师:金奇庭,1997
31.金奇庭.水质控制的物化法原理.西安建筑科技大学
32.佟玉衡.实用废水处理技术.北京.化学工业出版社,1998
33.唐受印等.水处理工程.北京.化学工业出版社,1999
34.林静雯.含铬、镍电镀废水的治理.环境保护科学,1999,26(4)
35.陈志勇等.漂白粉氧化处理化学镀镍废液的研究.Electroplating & Pollution Control Vol.21,No.4
36.彭昌盛等.电镀废水处理过程中的二次污染.Electroplating&Finihing,Vol.21
37.楼永通等.膜分离技术在镀镍漂洗水回收中的应用.Electroplaling&Pollution Control,Vol.21,No.5
38.任志华等.化学镀镍磷合金废液处理研究.表面工程,1997,3
39.分析化学,高等教育出版社,1995
40.物理化学,高等教育出版社,1998
41.印制电路版废水治理经验介绍.给水排水,1995,12:19
42.周绍民.金属电沉积——原理与研究方法.上海.上海科学技术出版社,1982.
43.曾华梁.电镀工艺手册.北京.机械工业出版社,1989.
44.高以恒等,膜分离技术用于电镀废水处理的发展与问题.北京工业大学学报,1990,16(3):86
45.姚锡禄.上海市电镀废水治理技术之进展.Electroplating&Pollution Control,1989,9(1):10
46.杨靖中.分步沉淀—絮凝法在电镀废水处理中的应用.环境污染与防治,1991,13(3):12
47.国家环保局水和废水监测分析方法编委会.水和废水监测分析方法.中国环境科学出版社,北京:1998
2.吴仲达等.电镀基本原理与实践.北京.机械工业出版社,1986
3.涂锦葆.电镀废水治理手册.北京.机械工业出版社,1989.
4.黄渭澄等.电度三废处理.成都.四川科学技术出版社,1983
5.张镜清.镍的毒性和含镍废水的治理.电镀与环保,1987,7(4):33~34
6.杜仰民.利用腐殖酸树脂处理镀镍废水.环境工程,1995,11(3):21~25
7.郑领英等.膜技术.北京.化学工业出版社,2000
8.王学松.反渗透技术及其在化工环保中的应用.北京.化学工业出版社,1988
9.王小文.超滤法处理碱法草浆黑液的试验研究.西安建筑科技大学硕士学位论文,导师:金奇庭,1998
10. A.S.Joeson, at al:The Application of Membrane Technology in the Pulp ang Paper Industry, Desalination, 1985,53:181
11.唐受印等.水处理工程师手册.北京.化学工业出版社,2001
12.[英]J.K.丹尼斯等著.镀镍和镀铬新技术.北京.科学技术文献出版社,1990
13.时钧等.膜技术手册.北京.化学工业出版社,2001
14.[日]中村实等著.电镀废水闭路循环的理论与应用.北京.机械工业出版社,1986
15.罗耀宗等.废槽边镀镍化学法处理含镍废水.1992,8(4):17
16.化学工业物性数据手册.有机卷.北京.化学工业出版社,1995
17.[美]Zahid.Amjad主编.反渗透—膜技术.水化学和工业应用.北京.化学工业出版社,1999
18.张自杰.排水工程(下)(第四版).北京.中国建筑工业出版社,1995
19. George C. Cushnie, Jr. ELECTROPLATING WASTERWATER POLLUTION CONTROL TECHNOLOGY. 1985
20.沈品华。电镀废水治理方法探讨.电镀与环保,1998,18(3):28~31
21.孟祥和等.重金属废水处理.北京.化学工业出版社,1999
22.崔志律,何为庆.工业废水处理.第二版.北京.冶金工业出版社,1999
23.电镀废水治理技术综述.北京.中国环境科学出版社,1992
24.王九思等.水处理化学.北京.化学工业出版社,2002
25.巩志坚,靳瑛.利用芬顿试剂处理焦化废水,工业水处理,1997,17(6):4~6,
26.云桂春,E·吉尔伯特,S·H·艾伯勒.用H_2O_2/Fe~(2+)处理含蒽醌—2—磺酸(ASA)染料
废水的实验研究,水处理技术,1987,13(4)
27.徐向荣,王文华,李华斌.Fenton 试剂处理酸性染料废水的研究,环境导报,1997,6:23~24
28.肖羽堂,许建华.利用芬顿试剂预处理难降解的二硝基氯化苯废水,重庆环境科学,1997,19(6):33~36
29.朱慎林等.环境化工技术及应用.北京.化学工业出版社,2003
30.刘旗龙.超滤在草浆黑液处理中的应用研究.西安建筑科技大学硕士学位论文,导师:金奇庭,1997
31.金奇庭.水质控制的物化法原理.西安建筑科技大学
32.佟玉衡.实用废水处理技术.北京.化学工业出版社,1998
33.唐受印等.水处理工程.北京.化学工业出版社,1999
34.林静雯.含铬、镍电镀废水的治理.环境保护科学,1999,26(4)
35.陈志勇等.漂白粉氧化处理化学镀镍废液的研究.Electroplating & Pollution Control Vol.21,No.4
36.彭昌盛等.电镀废水处理过程中的二次污染.Electroplating&Finihing,Vol.21
37.楼永通等.膜分离技术在镀镍漂洗水回收中的应用.Electroplaling&Pollution Control,Vol.21,No.5
38.任志华等.化学镀镍磷合金废液处理研究.表面工程,1997,3
39.分析化学,高等教育出版社,1995
40.物理化学,高等教育出版社,1998
41.印制电路版废水治理经验介绍.给水排水,1995,12:19
42.周绍民.金属电沉积——原理与研究方法.上海.上海科学技术出版社,1982.
43.曾华梁.电镀工艺手册.北京.机械工业出版社,1989.
44.高以恒等,膜分离技术用于电镀废水处理的发展与问题.北京工业大学学报,1990,16(3):86
45.姚锡禄.上海市电镀废水治理技术之进展.Electroplating&Pollution Control,1989,9(1):10
46.杨靖中.分步沉淀—絮凝法在电镀废水处理中的应用.环境污染与防治,1991,13(3):12
47.国家环保局水和废水监测分析方法编委会.水和废水监测分析方法.中国环境科学出版社,北京:1998